Mobility of Nonsticky Nanoparticles in Polymer Liquids

Cai, Li; Panyukov, Sergey; Rubinstein, Michael

doi:10.1021/ma201583q

Cited by 331 publications

(647 citation statements)

References 53 publications

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“…The idealized flow tracers are therefore "nonsticky" and roughly correspond to those considered in a recent publication [14]. In contrast to this, deformation tracers interact strongly with the elastic component and are bound within it.…”

Section: P-2 Localization and Diffusion Of Tracer Particles In Viscoementioning

confidence: 54%

Localization and diffusion of tracer particles in viscoelastic media with active force dipoles

Yasuda

Okamoto

Komura

et al. 2017

EPL

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-Optical tracking in vivo experiments reveal that diffusion of particles in biological cells is strongly enhanced in the presence of ATP and the experimental data for animal cells could previously be reproduced within a phenomenological model of a gel with myosin motors acting within it [EPL 110, 48005 (2015)]. Here, the two-fluid model of a gel is considered where active macromolecules, described as force dipoles, cyclically operate both in the elastic and the fluid components. Through coarse-graining, effective equations of motions for idealized tracer particles displaying local deformations and local fluid flows are derived. The equation for deformation tracers coincides with the earlier phenomenological model and thus confirms it. For flow tracers, diffusion enhancement caused by active force dipoles in the fluid component, and thus due to metabolic activity, is found. The latter effect may explain why ATP-dependent diffusion enhancement could also be observed in bacteria that lack molecular motors in their skeleton or when the activity of myosin motors was chemically inhibited in eukaryotic cells.

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Section: P-2 Localization and Diffusion Of Tracer Particles In Viscoementioning

confidence: 54%

Localization and diffusion of tracer particles in viscoelastic media with active force dipoles

Yasuda

Okamoto

Komura

et al. 2017

EPL

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“…Thus, the diffusivity of the cores remains almost constant when m > N c . 48 In the simulation, D C decreases as m increases and the dependence becomes weak above m ¼ 11. The transition chain length is N c ¼ 11 and the transition size R c of chains is then the hydrodynamic radius of the chain with m ¼ 11.…”

mentioning

confidence: 79%

Diffusivities, viscosities, and conductivities of solvent-free ionically grafted nanoparticles

Hong

Panagiotopoulos

2013

Soft Matter

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A new class of conductive composite materials, solvent-free ionically grafted nanoparticles, were modeled by coarse-grained molecular dynamics methods. The grafted oligomeric counterions were observed to migrate between different cores, contributing to the unique properties of the materials. We investigated the dynamics by analyzing the dependence on temperature and structural parameters of the transport properties (self-diffusion coefficients, viscosities and conductivities) and counterion migration kinetics. Temperature dependence of all properties follows the Arrhenius equation, but chain length and grafting density have distinct effects on different properties. In particular, structural effects on the diffusion coefficients are described by the Rouse model and the theory of nanoparticles diffusing in polymer solutions, viscosities are strongly influenced by clustering of cores, and conductivities are dominated by the motions of oligomeric counterions. We analyzed the migration kinetics of oligomeric counterions in a manner analogous to unimer exchange between micellar aggregates. The counterion migrations follow the "double-core" mechanism and are kinetically controlled by neighboring-core collisions.

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“…First, the mobility coefficient should be modified due to particle accumulation. According to the literature [31], in a polymer liquid, the mobility of nanoparticles can be affected by several factors, including particle size, solvent viscosity, and solute concentration. The mobility of particles decreases with solution volume fraction with the power relation D(n)~n −α , where α is the parameter to be determined under different experimental conditions.…”

Section: Theoretical Methodsmentioning

confidence: 99%

Simulation of Magnetically-Actuated Functional Gradient Nanocomposites

et al. 2017

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Abstract:Magnetically-actuated functional gradient nanocomposites can be locally modulated to generate unprecedented mechanical gradients that can be applied to various interfaces and surfaces through following the design principles of natural biological materials. However, a key question is how to modulate the concentration of magnetic particles using an external magnetic field. Here, we propose a model to obtain the gradient concentration distribution of magnetic particles and mechanical gradients. The results show that three states exist when the magnetic force changes in the z direction, including the unchanging state, the stable gradient state, and the over-accumulation state, which are consistent with experiment results. If both radial and axial magnetic forces are present, the inhomogeneity of magnetic-particle distribution in two dimensions was found to break the functional gradient. Furthermore, the size effects of a functional gradient sample were studied, which indicated that adjusting the magnetic force and diffusion constant would enable larger nanocomposites samples to generate functional gradients.

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Mobility of Nonsticky Nanoparticles in Polymer Liquids

Cited by 331 publications

References 53 publications

Localization and diffusion of tracer particles in viscoelastic media with active force dipoles

Localization and diffusion of tracer particles in viscoelastic media with active force dipoles

Diffusivities, viscosities, and conductivities of solvent-free ionically grafted nanoparticles

Simulation of Magnetically-Actuated Functional Gradient Nanocomposites

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